Robotically-assisted surgical device, robotically-assisted surgery method, and system

ABSTRACT

A robotically-assisted surgical device assists robotic surgery with a surgical robot including a robot arm, and includes a processing unit and a display unit. The processing unit acquires 3D data of a subject; acquires kinematic information of the robot arm; acquires information of a surgical procedure for operating; acquires position planning information for a plurality of ports to be pierced on a body surface of the subject; acquires measurement information obtained by measuring a position of a first port pierced on the body surface among the plurality of ports; determines a position of at least one of remaining ports other than the first port, based on the measurement information of the position of the first port, the information of the surgical procedure, the kinematic information, and the 3D data; and causes the display unit to display information indicating the determined position of the remaining port.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is based on and claims priority under 35 USC 119 fromJapanese Patent Application No. 2018-192930 filed on Oct. 11, 2018, thecontents of which are incorporated herein by reference.

TECHNICAL FIELD

The present disclosure relates to a robotically-assisted surgical devicethat assists robotic surgery with a surgical robot, arobotically-assisted surgery method, and a system.

BACKGROUND ART

In the related art, when minimally invasive robotic surgery is operatedusing a surgical robot, a port is pierced to insert forceps into a bodyof a patient being operated. The position of the port is approximatelydetermined depending on a surgical procedure, but the optimal positionthereof has yet to be established. US2014/0148816A discloses portplacement planning. Specifically, a surgical port placement systemdisclosed in US2014/0148816A generates a surgical port placement modelbased on a plurality of parameter sets associated with a plurality ofpast surgical procedures, receives a given parameter set for a givensurgical procedure including physical characteristics of a givenpatient, and plans at least one port position for the given patient forthe given surgical procedure based on the given parameter set and thesurgical port placement model.

SUMMARY OF INVENTION

The present disclosure provides a robotically-assisted surgical devicecapable of reducing the influence of misplacement of a pre-pierced port(a port that has been previously pierced) on robotic surgery, arobotically-assisted surgery method, and a system.

According to one aspect of the disclosure, a robotically-assistedsurgical device assists minimally invasive robotic surgery with asurgical robot that includes at least one robot arm holding a surgicalinstrument. The robotically-assisted surgical device includes aprocessing unit and a display unit. The processing unit is configuredto: acquire 3D data of a subject; acquire kinematic information regardto the robot arm; acquire information of a surgical procedure foroperating the subject; acquire position planning information for aplurality of ports which are to be pierced on a body surface of thesubject; acquire measurement information obtained by measuring aposition of a first port which is pierced on the body surface among theplurality of ports; determine a position of at least one of remainingports other than the first port among the plurality of ports, based onthe measurement information of the position of the first port, theinformation of the surgical procedure, the kinematic information, andthe 3D data; and cause the display unit to display informationindicating the determined position of the at least one of remainingports.

According to another aspect of the disclosure, a robotically-assistedsurgery method is a method of a robotically-assisted surgical devicethat assists robotic surgery with a surgical robot that includes atleast one robot arm holding a surgical instrument. Therobotically-assisted surgery method includes: acquiring 3D data of asubject; acquiring kinematic information regard to a moving part of thesurgical robot for performing the robotic surgery; acquiring informationof a surgical procedure for operating the subject; acquiring positionplanning information for a plurality of ports which are to be pierced ona body surface of the subject; acquiring measurement informationobtained by measuring a position of a first port which is pierced on thebody surface among the plurality of ports; determining a position of atleast one of remaining ports other than the first port among theplurality of ports, based on the measurement information of the positionof the first port, the information of the surgical procedure, thekinematic information, and the 3D data; and causing a display unit todisplay information indicating the determined position of the at leastone of remaining ports.

According to further another aspect of the disclosure, arobotically-assisted surgery system is a system of arobotically-assisted surgical device that assists robotic surgery with asurgical robot that includes at least one robot arm holding a surgicalinstrument. The robotically-assisted surgery system includes, acquiring3D data of a subject; acquiring kinematic information regard to a movingpart of the surgical robot for performing the robotic surgery; acquiringinformation of a surgical procedure for operating the subject; acquiringposition planning information for a plurality of ports which are to bepierced on a body surface of the subject; acquiring measurementinformation obtained by measuring a position of a first port which ispierced on the body surface among the plurality of ports; determining aposition of at least one of remaining ports other than the first portamong the plurality of ports, based on the measurement information ofthe position of the first port, the information of the surgicalprocedure, the kinematic information, and the 3D data; and causing adisplay unit to display information indicating the determined positionof the at least one of remaining ports.

According to the present disclosure, the present disclosure can suppressdeterioration in workability of robotic surgery by a surgical robot

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is a block diagram illustrating a hardware configuration exampleof a robotically-assisted surgical device according to a firstembodiment;

FIG. 2 is a block diagram illustrating a functional configurationexample of the robotically-assisted surgical device;

FIG. 3 is a view illustrating examples of MPR images of an abdomenbefore and after performing a pneumoperitoneum simulation;

FIG. 4 is a view illustrating a measurement example of a port positionof a pre-pierced port;

FIG. 5A is a view illustrating a first placement planning example ofport positions placed on a body surface of a subject;

FIG. 5B is a view illustrating a second placement planning example ofport positions placed on the body surface of the subject;

FIG. 5C is a view illustrating a third placement planning example ofport positions placed on the body surface of the subject;

FIG. 6 is a view illustrating an example of a positional relationshipbetween the subject, ports, trocars, and robot arms during roboticsurgery;

FIG. 7 is a flowchart illustrating an example of a procedure of a portposition simulation by the robotically-assisted surgical device;

FIG. 8 is a flowchart illustrating an operation example when a portposition score is calculated by the robotically-assisted surgicaldevice;

FIG. 9 is a view illustrating an example of working areas determinedbased on port positions;

FIG. 10 is a flowchart illustrating an example of a port positionadjustment procedure using the pre-pierced port by therobotically-assisted surgical device;

FIG. 11A is a view illustrating an image display example including aguide display before piercing a port;

FIG. 11B is a view illustrating an image display example including aguide display after piercing the port;

FIG. 12 is a view illustrating a designation example of port positionsaccording to Comparative Example;

FIG. 13 is a view illustrating a designation example of port positionsaccording to the first embodiment; and

FIG. 14 is a view illustrating designation of a piercing position on a2D plane and misplacement of the piercing position in a 3D space.

DESCRIPTION OF EMBODIMENTS

Hereinafter, embodiments of the present disclosure will be describedusing the drawings.

In the present disclosure, a robotically-assisted surgical deviceassists minimally invasive robotic surgery with a surgical robot thatincludes at least one robot arm holding a surgical instrument. Therobotically-assisted surgical device includes a processing unit and adisplay unit. The processing unit is configured to: acquire 3D data of asubject; acquire kinematic information regard to the robot arm; acquireinformation of a surgical procedure for operating the subject; acquireposition planning information for a plurality of ports which are to bepierced on a body surface of the subject; acquire measurementinformation obtained by measuring a position of a first port which hasbeen pierced on the body surface among the plurality of ports; determinea position of at least one of remaining ports other than the first portamong the plurality of ports, based on the acquired measurementinformation of the position of the first port, the acquired informationof the surgical procedure, the acquired kinematic information, and theacquired 3D data; and cause the display unit to display informationindicating the determined position of the at least one of remainingports.

According to the present disclosure, even when one port is pierced at aposition misplaced from the piercing-planned position, therobotically-assisted surgical device can adjust the remaining portpositions in consideration of the port position of the pre-pierced port.Accordingly, even when the operation efficiency or the safety of roboticsurgery is likely to deteriorate with the derived combination of theplurality of port positions due to the error of the piercing position ofthe pre-pierced port, deterioration in the operation efficiency and thesafety can be suppressed by replacing the remaining port positions inconsideration of the pre-pierced port.

Circumstances for Achievement of Aspect of Present Disclosure

In some cases, an assistant pierces a port according to preoperativeplanning. However, it is difficult to accurately pierce a port at aplanned port position. When a port position to be pierced ispreoperatively planned on a 2D plane, for example, a port is planned tobe pierced at a position at a distance L1 from a navel, as illustratedin FIG. 14, even with the same distance on the 2D plane, the positionlargely changes in a forward-backward direction of a subject as it movestoward a lateral part of the subject (refer to a range α). Therefore, itis difficult to accurately perform the measurement and to uniquelydetermine a port position to be pierced during port piercing.

In addition, in robotic surgery, pneumoperitoneum is performed in manycases. During pneumoperitoneum, carbon dioxide gas is injected into anabdominal cavity to secure a working space in the abdominal cavity.Since the degree of elevation of abdominal wall varies depending on thepneumoperitoneum state, a 3D position planned on a body surface of apatient is also variable.

Therefore, a port may be pierced at a position misplaced from a plannedport position. In port position planning, a combination of a pluralityof ports is planned. However, when one port position among the pluralityof port positions is misplaced, during robotic surgery using a port setincluding this port position, the workability of a surgical robot maydeteriorate. For example, when a pierced port position (pre-piercedport) is misplaced from a planned port position, there may be a regionthat cannot be reached by forceps in a body of a patient, or robot armswith forceps that are included in a surgical robot may come into contactwith each other such that a movable range of the robot arms is limited.In addition, during minimally invasive surgery using a surgical robot,application of stress to a port is limited as compared to the minimallyinvasive surgery by persons.

In the following embodiment, a robotically-assisted surgical devicecapable of reducing the influence of misplacement of a pre-pierced porton robotic surgery, a robotically-assisted surgery method, and a systemwill be described.

First Embodiment

FIG. 1 is a block diagram illustrating a configuration example of arobotically-assisted surgical device 100 according to a firstembodiment. The robotically-assisted surgical device 100 assists roboticsurgery with a surgical robot 300 and performs, for example, apreoperative simulation, an intraoperative simulation, andintraoperative navigation.

The surgical robot 300 includes a robot operation terminal, a robot mainbody, and an image display terminal.

The robot operation terminal includes a hand controller or a foot switchmanipulated by an operator. The robot operation terminal operates aplurality of robot arms AR provided in the robot main body according toa manipulation of the hand controller or the footswitch by the operator.In addition, the robot operation terminal includes a viewer. The viewermay be a stereo viewer and may merge images input through an endoscopeto display a 3D image. A plurality of robot operation terminals may bepresent such that a plurality of operators operate the plurality ofrobot operation terminals to perform robotic surgery.

The robot main body includes: a plurality of robot arms for performingrobotic surgery; and an end effector EF (forceps, an instrument) as asurgical instrument that is mounted on the robot arm AR.

The robot main body of the surgical robot 300 includes four robot armsAR including: a camera arm on which an endoscope camera is mounted; afirst end effector arm on which an end effector EF operated by aright-hand controller of the robot operation terminal is mounted; asecond end effector arm on which an end effector EF operated by aleft-hand controller of the robot operation terminal is mounted; and athird end effector arm on which an end effector EF for replacement ismounted. Each robot arm AR includes a plurality of joints and includes amotor and an encoder corresponding to each joint. Each robot arm AR hasat least 6 degrees of freedom and preferably 7 or 8 degrees of freedom,operates in a 3D space, and may be movable in each direction in the 3Dspace. The end effector EF is an instalment that actually comes intocontact with a treatment target in a subject PS during robotic surgery,and can perform various treatments (for example, gripping, dissection,exfoliation, or suture).

Examples of the end effector EF may include gripping forceps,exfoliating forceps, an electric knife, and the like. A plurality ofdifferent end effectors EF may be prepared for respective functions. Forexample, in robotic surgery, a treatment of dissecting a tissue with oneend effector EF while holding or pulling the tissue with two endeffectors EF may be performed. The robot arm AR and the end effector EFmay operate based on an instruction from the robot operation terminal.

The image display terminal includes a monitor, a controller forprocessing an image captured by a camera of an endoscope to display theimage on a viewer or a monitor, and the like. The monitor is checked by,for example, an assistant of robotic surgery or a nurse.

The surgical robot 300 receives a manipulation of the hand controller orthe footswitch of the robot operation terminal by the operator, controlsthe operation of the robot arm AR or the end effector EF of the robotmain body, and performs robotic surgery in which various treatments areperformed on the subject PS. In robotic surgery, laparoscopic surgery isperformed in the subject PS.

In robotic surgery, a port PT is pierced on the body surface of thesubject PS, and pneumoperitoneum is performed through the port PT. Inpneumoperitoneum, carbon dioxide may be injected to inflate theabdominal cavity of the subject PS. In the port PT, a trocar TC may beprovided. The trocar TC includes a valve and maintains the inside of thesubject PS to be airtight. In addition, in order to maintain theairtight state, air (for example, carbon dioxide) is intermittentlyintroduced into the subject PS.

The end effector EF (shaft of the end effector EF) is inserted into thetrocar TC. The valve of the trocar TC is opened during insertion of theend effector EF and is closed during the separation of the end effectorEF. The end effector EF is inserted from the port PT through the trocarTC such that various treatments are performed according to the surgicalprocedure. Robotic surgery may be applied to not only laparoscopicsurgery in which the surgery target is the abdomen but also arthroscopicsurgery in which the surgery target includes a region other than theabdomen.

As illustrated in FIG. 1, the robotically-assisted surgical device 100includes a communication unit 110, a user interface (UI) 120, a display130, a processor 140, and a memory 150. The UI 120, the display 130, andthe memory 150 may be included in the robotically-assisted surgicaldevice 100 or may be provided separately from the robotically-assistedsurgical device 100.

A CT (Computed Tomography) apparatus 200 is connected to therobotically-assisted surgical device 100 through the communication unit110. The robotically-assisted surgical device 100 acquires volume datafrom the CT apparatus 200 and processes the acquired volume data. Therobotically-assisted surgical device 100 may be configured by a PC(Personal Computer) and software installed on the PC. Therobotically-assisted surgical device 100 may be configured as a part ofthe surgical robot 300.

The surgical robot 300 is connected to the robotically-assisted surgicaldevice 100 through the communication unit 110. The robotically-assistedsurgical device 100 may provide various data, information, or imagesfrom, for example, the surgical robot 300 to assist robotic surgery. Therobotically-assisted surgical device 100 may acquire, from, for example,the surgical robot 300, information regarding a mechanism or theoperation of the surgical robot 300 or data obtained before, during, orafter robotic surgery such that various kinds of analysis orinterpretation can be performed based on the acquired information ordata. The analysis result or the interpretation result may bevisualized.

A measuring instrument 400 is connected to the robotically-assistedsurgical device 100 through the communication unit 110. The measuringinstrument 400 may measure information (for example, a body surfaceposition of the subject PS) regarding the subject PS (for example, apatient) to be operated by the surgical robot 300. The measuringinstrument 400 may measure a position of the port PT provided on thebody surface of the subject PS. The measuring instrument 400 may be, forexample, a depth sensor 410. The depth sensor 410 may be included in thesurgical robot 300 (for example, the robot main body) or may be providedin the ceiling or the like of an operating room where robotic surgery isperformed. In addition, the measuring instrument 400 may receive aninput of the result of manual measurement of an operation unit of themeasuring instrument 400. In the manual measurement, for example,information regarding a patient or a port position on the body surfacemay be measured by a ruler or a tape measure.

In addition, the CT apparatus 200 is connected to therobotically-assisted surgical device 100. Alternatively, instead of theCT apparatus 200, a device capable of capturing various images may beconnected to the robotically-assisted surgical device 100. This devicemay be, for example, an angiographic device or an ultrasound device.This device may be used to check the internal state of the subject PSbefore and during robotic surgery.

The CT apparatus 200 irradiates an organism with X-rays and acquiresimages (CT images) using a difference in X-ray absorption depending ontissues. The subject PS may be, for example, a human body or anorganism. The subject PS may not be a human body nor an organism. Forexample, the subject PS may be an animal or a phantom for surgicaltraining.

A plurality of CT images may be acquired m a time series. The CTapparatus 200 generates volume data including information regarding anyportion inside the organism. Here, any portion inside the organism mayinclude various organs (for example, brain, heart, kidney, colon,intestine, lung, chest, lacteal gland, and prostate gland). By acquiringthe CT image, it is possible to obtain a pixel value (CT value, voxelvalue) of each pixel (voxel) of the CT image. The CT apparatus 200transmits the volume data as the CT image to the robotically-assistedsurgical device 100 via a wired circuit or a wireless circuit.

Specifically, the CT apparatus 200 includes a gantry (not illustrated)and a console (not illustrated). The gantry includes an X-ray generator(not illustrated) and an X-ray detector (not illustrated) and acquiresimages at a predetermined timing instructed by the console to detect anX-ray transmitted through the subject PS and to obtain X-ray detectiondata. The X-ray generator includes an X-ray tube (not illustrated). Theconsole is connected to the robotically-assisted surgical device 100.The console acquires a plurality of X-ray detection data from the gantryand generates volume data based on the X-ray detection data. The consoletransmits the generated volume data to the robotically-assisted surgicaldevice 100. The console may include an operation unit (not illustrated)for inputting patient information, scanning conditions regarding CTscanning, contrast enhancement conditions regarding contrast mediumadministration, and other information. This operation unit may includean input device such as a keyboard or a mouse.

The CT apparatus 200 continuously captures images to acquire a pluralityof 3D volume data such that a moving image can also be generated. Dataof the moving image generated the plurality of 3D volume data will alsobe referred to as 4D (four-dimensional) data.

The CT apparatus 200 may capture CT images at each of a plurality oftimings. The CT apparatus 200 may capture a CT image in a state wherethe subject PS is contrast-enhanced. The CT apparatus 200 may capture aCT image in a state where the subject PS is not contrast-enhanced.

In the robotically-assisted surgical device 100, the communication unit110 performs communication of various data or information with otherdevices. The communication unit 110 may perform communication of variousdata with the CT apparatus 200, the surgical robot 300, and themeasuring instrument 400. The communication unit 110 performs wiredcommunication or wireless communication The communication unit 110, maybe connected to the CT apparatus 200, the surgical robot 300, and themeasuring instrument 400 in a wired or wireless manner.

The communication unit 110 may acquire various information for roboticsurgery from the surgical robot 300. The various information mayinclude, for example, kinematic information of the surgical robot 300.The communication unit 110 may transmit various information for roboticsurgery to the surgical robot 300. The various information may include,for example, information (for example, an image or data) generated by aprocessing unit 160.

The communication unit 110 may acquire various information for roboticsurgery from the measuring instrument 400. The various information mayinclude, for example, position information of the body surface of thesubject PS or information of a port position pierced on the body surfaceof the subject PS that is measured by the measuring instrument 400.

The communication unit 110 may acquire volume data from the CT apparatus200. The acquired volume data may be transmitted immediately to theprocessor 140 for various processes, or may be stored in the memory ISOfirst and then transmitted to the processor 140 for various processes asnecessary. In addition, the volume data may be acquired via a recordingmedium.

The volume data acquired by the CT apparatus 200 may be transmitted fromthe CT apparatus 200 to an image data server such as (PACS: PictureArchiving and Communication Systems; not illustrated) and storedtherein, instead of acquiring from the CT apparatus 200, thecommunication unit 110 may acquire volume data from the image dataserver. This way, the communication unit 110 functions as an acquisitionunit that acquires various data such as volume data.

The UI 120 may include a touch panel, a pointing device, a keyboard, ora microphone. The UI 120 receives an input operation from a user of therobotically-assisted surgical device 100. The user may include a doctor,a radiographer, or other paramedic staffs. The doctor may include anoperator that manipulates the robot operation terminal to operaterobotic surgery or an assistant that assists robotic surgery near thesubject PS.

The UI 120 receives an operation such as a designation of a region ofinterest (ROI), a setting of luminance conditions, and the like in thevolume data. The region of interest may include various tissues (such asblood vessels, bronchial tubes, organs, bones, brain, heart, feet, neck,and blood flow). The tissues may broadly include tissues of the subjectPS such as diseased tissue, normal tissue, organs, and parts. Inaddition, the UI 120 may receive an operation such as a designation ofthe region of interest or a setting of luminance conditions in thevolume data with respect to an image (for example, a 3D image or a 2Dimage described below) based on the volume data.

The display 130 may include a Liquid Crystal Display (LCD) and displaysvarious information. The various information may include a 3D image or a2D image obtained from the volume data. The 3D image may include, forexample, a volume rendering image, a surface rendering image, a virtualendoscope image (VE image), a virtual ultrasound image, or a CurvedPlanar Reconstruction (CPR) image. The volume rendering image mayinclude a RaySum image (also simply referred to as “SUM image”), aMaximum Intensity Projection (MIP) image, a Minimum Intensity Projection(MinIP) image, an average image, or a Raycast image. The 2D image mayinclude an axial image, a sagittal image, a coronal image, a MultiPlanar Reconstruction (MPR) image, or the like. The 3D image and the 2Dimage may include a color fusion image.

The memory 150 includes a primary storage device such as various ReadOnly Memories (ROM) or Random Access Memory (RAM). The memory 150 mayinclude a secondary storage device such as a Hard Disk Drive (HDD) or aSolid State Drive (SSD). The memory 150 may include a third storagedevice such as a USB memory or an SD card. The memory 150 stores variousinformation. The various information includes information acquired viathe communication unit 110, information and an image generated from theprocessor 140, setting information set by the processor 140, and variousprograms. The information acquired via the communication unit 110 mayinclude, for example, information from the CT apparatus 200 (forexample, volume data), information from the surgical robot 300,information from the measuring instrument 400, and information from anexternal server. The memory 150 is an example of a non-transitoryrecording medium in which a program is recorded.

A projection unit 170 projects visible light (for example, laser light)to the subject. The projection unit 170 projects the visible light todisplay various information (for example, the information of the portposition) on the body surface of the subject PS (for example, the bodysurface of the abdomen). The visible light, that is, the informationdisplayed on the body surface of the subject PS is recognized by theusers (for example, an assistant).

The processor 140 may include a Central Processing Unit (CPU), a DigitalSignal Processor (DSP), or a Graphical Processing Unit (GPU). Theprocessor 140 executes the program stored in the memory 150 to functionas the processing unit 160 controlling various processes and controls.

FIG. 2 is a block diagram illustrating a functional configurationexample of the processing unit 160.

The processing unit 160 includes a region segmentation unit 161, animage generator 162, a deformation simulator 163, a port positionprocessing unit 164, a display controller 166, and a projectioncontroller 167.

The processing unit 160 integrates the respective units of therobotically-assisted surgical device 100. The respective sectionsincluded in the processing unit 160 may be Implemented as differentfunctions by one piece of hardware or may be implemented as differentfunctions by a plurality of pieces of hardware. In addition, therespective sections included in the processing unit 160 may beimplemented by a dedicated hardware component.

The region segmentation unit 161 may perform segmentation processing inthe volume data. In this case, the UI 120 receives an instruction from auser and transmits information of the instruction to the regionsegmentation unit 161. The region segmentation unit 161 may performsegmentation processing from the volume data based on the information ofthe instruction using a well-known method to segment the region ofinterest. In addition, the region of interest may be set manually inaccordance with the specific instruction from the user. In addition,when an observation target is predetermined, the region segmentationunit 161 may perform segmentation processing from the volume data tosegment the region of interest including the observation target withoutthe user instruction. The segmented region may include regions ofvarious tissues (for example, blood vessels, bronchial tubes, organs,bones, brain, heart, feet, neck, blood flow, lacteal gland, chest, andtumor). The observation target may be a target to be treated by roboticsurgery.

The image generator 162 may generate a 3D image or a 2D image based onthe volume data acquired from the communication unit 110. The imagegenerator 162 may generate a 3D image or a 2D image from the volume dataacquired from the communication unit 110 based on a designated region orthe region segmented by the region segmentation unit 161.

The deformation simulator 163 may perform a process relating todeformation in the subject PS as a surgery target. For example, thedeformation simulator 163 may perform a pneumoperitoneum simulation ofvirtually performing pneumoperitoneum on the subject PS. A specificmethod of the pneumoperitoneum simulation may be a well-known method,for example, a method described in Takayuki Kitasaka, Kensaku Mori,Yuichiro Hayashi, Yasuhito Suenaga, Makoto Hashizume, and JunichiroToriwaki, “Virtual Pneumoperitoneum for Generating Virtual LaparoscopicViews Based on Volumetric Deformation”, MICCAI (Medical Image Computingand Computer-Assisted Intervention), 2004, P559-P567 which isincorporated herein by reference. That is, the deformation simulator 163may perform the pneumoperitoneum simulation based on the volume data(volume data before pneumoperitoneum (non-pneumoperitoneum state))acquired from the communication unit 110 or the region segmentation unit161 to generate volume data after pneumoperitoneum (volume data in thepneumoperitoneum state). Through the pneumoperitoneum simulation, theuser can simulate a state where pneumoperitoneum is performed on thesubject PS without actually performing pneumoperitoneum on the subjectPS to observe a state where pneumoperitoneum is virtually performed.Among pneumoperitoneum states, a state of pneumoperitoneum estimated bythe pneumoperitoneum simulation will be referred to as “a virtualpneumoperitoneum state”, and a state where pneumoperitoneum is actuallyperformed will also be referred to as “an actual pneumoperitoneumstate”.

FIG. 3 is a view illustrating examples of MPR images of the abdomenbefore and after performing the pneumoperitoneum simulation. An imageG11 illustrate the state before performing the pneumoperitoneumsimulation, which is a state (non-pneumoperitoneum state) where theabdomen of the subject PS is not inflated. An image G12 illustrate thestate after performing the pneumoperitoneum simulation, which is a state(virtual pneumoperitoneum state) where the abdomen of the subject PS isinflated and includes a pneumoperitoneum space KS. In robotic surgery,the subject PS is operated in the pneumoperitoneum state. Therefore, thepneumoperitoneum simulation is performed on the volume data acquired inthe non-pneumoperitoneum state by the deformation simulator 163 and thevolume data in the virtual pneumoperitoneum state is derived.

The deformation simulator 163 may virtually deform the observationtarget such as an organ or a disease in the subject PS. The observationtarget may be a surgery target to be operated by the operator. Thedeformation simulator 163 may simulate a state where an organ is pulled,pressed, or dissected by the end effector EF. In addition, thedeformation simulator 163 may simulate, for example, movement of anorgan by a postural change.

The port position processing unit 164 acquires information of aplurality of ports PT provided on the body surface of the subject PS.The information of the port PT may include, for example, identificationinformation of the port PT, information regarding a position (portposition) on the body surface of the subject PS where the port PT ispierced, information regarding the size of the port PT, or the like. Theinformation of a plurality of ports may be stored in the memory 150 orthe external server as a template. The information of the plurality ofports may be determined according to the surgical procedure. Theinformation of the plurality of ports may be used for preoperativeplanning.

The port position processing unit 164 may acquire the information of theplurality of ports positions from the memory 150. The port positionprocessing unit 164 may acquire the information of the plurality of portpositions from the external server via the communication unit 110. Theport position processing unit 164 may receive a designation of portpositions of the plurality of ports PT via the UI 120 to acquire theinformation of the plurality of port positions. The information of theplurality of ports may be the information of a combination of theplurality of port positions.

The port position processing unit 164 acquires kinematic information ofthe surgical robot 300. The kinematic information may be stored in thememory 150. The port position processing unit 164 may acquire thekinematic information from the memory 150. The port position processingunit 164 may acquire the kinematic information from the surgical robot300 or the external server via the communication unit 110. The kinematicinformation may vary depending on the surgical robot 300.

The kinematic information may include, for example, shape informationregarding the shape of an instrument (for example, the robot arm AR orthe end effector EF) for robotic surgery included in the surgical robot300 or operation information regarding the operation thereof. This shapeinformation may include information of at least a part, for example, thelength or weight of each portion of the robot arm AR or the end effectorEF, the angle of the robot arm AR with respect to a reference direction(for example, a horizontal plane), or the inclination angle of the endeffector EF with respect to the robot arm AR. This operation informationmay include information of at least a part, for example, the movablerange of the robot arm AR or the end effector EF in the 3D space, theposition, velocity; or acceleration of the robot arm AR during theoperation of the robot arm AR, or the position, velocity, oracceleration of the end effector EF relative to the robot arm AR duringthe operation of the end effector EF.

In kinematics, not only the movable range of one robot arm but also themovable range of another robot arm are regulated. Accordingly, thesurgical robot 300 operates based on the kinematics of each robot arm ARof the surgical robot 300, and therefore, interference between theplurality of robot arms AR during operation can be avoided.

The port position processing unit 164 acquires information of thesurgical procedure. The surgical procedure refers to the procedure ofsurgery on the subject PS. The surgical procedure may be designated viathe UI 120. Each treatment in robotic surgery may be determineddepending on the surgical procedure. Depending on the treatment, the endeffector EF required for the treatment may be determined. Accordingly,the end effector EF mounted on the robot arm AR may be determineddepending on the surgical procedure, and the type of the end effector EFmounted on the robot arm AR may be determined depending on the surgicalprocedure. In addition, a minimum region that is required for thetreatment or a recommended region that is recommended to be secured forthe treatment may be determined depending on the treatment.

The port position processing unit 164 acquires information of a targetregion. The target region may be a region including targets (forexample, tissues (such as blood vessels, bronchial tubes, organs, bones,brain, heart, feet, and neck) to be treated by robotic surgery. Thetissues may broadly include tissues of the subject PS such as diseasedtissues, normal tissues, organs, and parts.

The port position processing unit 164 may acquire information regardingthe position of the target region from the memory 150. The port positionprocessing unit 164 may acquire the information of the position of thetarget region from the external server via the communication unit 110.The port position processing unit 164 may receive a designation of theposition of the target region via the UI 120 to acquire the informationregarding the position of the target region.

The port position processing unit 164 may execute a port positionsimulation. The port position simulation may be a simulation in whichthe user operates the UI 120 to determine whether or not desired roboticsurgery can be performed on the subject PS. In the port positionsimulation, while simulating surgery, the user may operate the endeffector EF inserted into each of the port positions in a virtual spaceto determine whether or not the target region as a surgery target isaccessible. That is, in the port position simulation, while receivingthe manual operation of the surgical robot 300, the user may determinewhether or not a moving part (for example, the robot arm AR and the endeffector EF) of the surgical robot 300 relating to robotic surgery isaccessible to the target region as a surgery target without a problem.The port position processing unit 164 may obtain port position planninginformation through the port position simulation.

In the port position simulation, whether or not the target region isaccessible may be determined based on the volume data of the subject PS,the acquired combination of the plurality of port positions, thekinematics of the surgical robot 300, the surgical procedure, the volumedata of the virtual pneumoperitoneum state, and the like. While changingthe plurality of port positions on the body surface of the subject PS,the port position processing unit 164 may determine whether or not thetarget region is accessible at each port position or may sequentiallyperform the port position simulation. The port position processing unit164 may designate information regarding a finally preferable (forexample, optimal) combination of port positions according to the userinput via the UI 120. As a result, the port position processing unit 164may plan the plurality of port positions to be pierced. The details ofthe port position simulation will be described below.

Using the plurality of port positions provided on the body surface ofthe subject PS, the port position processing unit 164 may derive (forexample, calculate) a port position score representing theappropriateness for robotic surgery. That is, the port position scorebased on the combination of the plurality of port positions indicatesthe value of the combination of the plurality of port positions forrobotic surgery. The port position score may be calculated based on thecombination of the plurality of port positions, the kinematics of thesurgical robot 300, the surgical procedure, the volume data of thevirtual pneumoperitoneum state, and the like. The port position score isderived for each port position. The details of the port position scorewill be described below.

The port position processing unit 164 may adjust the port position basedon the port position score. In this case, the port position processingunit 164 may adjust the port position based on the variation of the portposition score according to the movement of the port position. Thedetails of the port position adjustment will be described below.

As described above, the port position processing unit 164 may derive theplurality of port positions to be pierced according to the port positionsimulation. In addition, the port position processing unit 164 mayderive the plurality of port positions to be pierced based on the portposition score.

The display controller 166 causes the display 130 to display variousdata, information, or images. The display controller 166 may display the3D image or the 2D image generated by the image generator 162. Thedisplay controller 166 may display an image showing the information ofthe plurality of ports PT (for example, the information of the portpositions) generated by the image generator 162.

The display controller 166 may display an image showing the informationof remaining ports (for example, the information of the port positions)other than a pre-pierced port PT1, which is a port PT that is previouslypierced, among the plurality of ports PT generated by the imagegenerator 162. In this case, the display controller 166 may display theimage showing the plurality of port positions or the image showing theremaining port positions to superimpose the 3D image or the 2D image.The remaining ports may be ports (non-pierced ports) that have been notyet pierced.

The projection controller 167 controls the projection of the visiblelight from the projection unit 170. The projection controller 167 maycontrol, for example, a frequency or an intensity of the visible light,a position to which the visible light is projected, or a timing at whichthe visible light is projected.

The projection controller 167 causes the projection unit 170 to projectthe visible light to the subject PS and displays various information onthe body surface of the subject PS (for example, the body surface of theabdomen). The projection controller 167 may project laser light to thebody surface of the subject PS to mark a specific position on the bodysurface. The specific position may be, for example, the port position tobe pierced or a position on the volume data where the observation target(for example, the affected part) is present when shifted from thespecific position on the body surface in the normal direction. That is,the projection controller 167 may be a laser pointer indicating the portposition.

In addition, the projection controller 167 may cause the projection unit170 to project the visible light to the body surface of the subject PSto superimpose and display information assistant robotic surgery (forexample, the information regarding the port position) on the bodysurface of the subject PS. The superimposing information may be, forexample, character information or graphic information. That is, theprojection controller 167 may assist the user in robotic surgery usingan augmented reality (AR) technique.

FIG. 4 is a view illustrating a measurement example of a port positionof the pre-pierced port PT1. The measurement of the port position may bethe 3D measurement. In FIG. 4, the subject PS (for example, a patient)is horizontally placed on a bed BD.

The depth sensor 410 may include: a light-emitting portion that emitsinfrared light; a light-receiving portion that receives infrared light;and a camera that captures an image. The depth sensor 410 may detect thedistance from the depth sensor 410 to the subject PS based on theinfrared light that is emitted from the light-emitting portion to thesubject PS and reflected light that is reflected from the subject PS andreceived by the light-receiving portion. The depth sensor 410 may detectthe upper, lower, left, and right sides of an object using the imagecaptured by the camera. As a result, the depth sensor 410 may acquireinformation of a 3D position (3D coordinates) of each position (forexample, the port position of the pre-pierced port PT1) on the bodysurface of the subject PS.

The depth sensor 410 may include a processor and an internal memory. Theinternal memory may store information regarding the shape of the trocarTC. Referring to the shape information of the trocar TC stored in theinternal memory, the depth sensor 410 may detect (recognize) the trocarTC provided in the port PT pierced on the body surface of the subject PSto detect (measure) a 3D position of the trocar TC.

In addition, a predetermined mark may be formed on a surface of thetrocar TC. The depth sensor 410 may capture an image using thepredetermined mark on the trocar TC as a feature point to detect(recognize) the trocar TC by image recognition. As a result, the depthsensor 410 can improve the recognition accuracy of the trocar TC and canimprove the measurement accuracy of the 3D position of the trocar TC.

In addition, the depth sensor 410 may include a stereo camera instead ofthe infrared sensor (the light-emitting portion and the light-receivingportion) such that the 3D position of the trocar TC can be measured byimage processing. In this case, the depth sensor 410 may measure the 3Dposition of the trocar TC by recognizing the trocar TC by objectrecognition in an image captured by a stereo camera, detecting(recognizing) the position of the trocar TC on the body surface of thesubject, and calculating the distance to the trocar TC.

The depth sensor 410 may measure each position or the position of thetrocar TC on the body surface of the subject PS in a range that can bereached by the infrared light emitted from the infrared sensor or in arange where an image can be captured by the camera (refer to a range A1in FIG. 4).

The deformation simulator 163 of the robotically-assisted surgicaldevice 100 may acquire information regarding each position on the bodysurface of the subject PS in the actual pneumoperitoneum state, that is,information regarding the shape of the body surface of the subject PS inthe actual pneumoperitoneum state from the depth sensor 410. Inaddition, the deformation simulator 163 may extract the contour(corresponding to the body surface) of the subject PS based on thevolume data of the subject PS in the non-pneumoperitoneum state toacquire information regarding each position on the body surface of thesubject PS in the non-pneumoperitoneum state, that is, informationregarding the shape of the body surface of the subject PS in thenon-pneumoperitoneum state.

The deformation simulator 163 may calculate a difference between eachposition on the body surface of the subject PS in the actualpneumoperitoneum state and each position on the body surface of thesubject PS in the non-pneumoperitoneum state, that is, a differencebetween the shape of the body surface of the subject PS in the actualpneumoperitoneum state and the shape of the body surface of the subjectPS in the non-pneumoperitoneum state. As a result, the deformationsimulator 163 can recognize the amount of pneumoperitoneum for allowingthe actual pneumoperitoneum state of the subject PS.

In addition, the deformation simulator 163 may correct a simulationmethod or a simulation result of the pneumoperitoneum simulation basedon the difference between the actual pneumoperitoneum state and thevirtual pneumoperitoneum state in the pneumoperitoneum simulation. Thatis, the deformation simulator 163 may correct a simulation method or asimulation result of the pneumoperitoneum simulation based on the actualamount of pneumoperitoneum. The deformation simulator 163 may store thecorrection information in the memory 150. In addition, the deformationsimulator 163 may receive the amount of scavenging air from apneumoperitoneum device via the communication unit 110 to correct asimulation method or a simulation result of the pneumoperitoneumsimulation. As a result, the robotically-assisted surgical device 100can improve the accuracy of the pneumoperitoneum simulation.

Next, an example of displaying a port position will be described.

The deformation simulator 163 performs the pneumoperitoneum simulationon the volume data obtained in the non-pneumoperitoneum state (forexample, by preoperative CT scanning) to generate the volume data of thevirtual pneumoperitoneum state. The image generator 162 may performvolume rendering on the volume data of the virtual pneumoperitoneumstate to generate a volume rendering image. The image generator 162 mayperform surface rendering on the volume data of the virtualpneumoperitoneum state to generate a surface rendering image.

The deformation simulator 163 may perform the pneumoperitoneumsimulation on the volume data obtained in the non-pneumoperitoneum suite(for example, by preoperative CT scanning) to generate deformationinformation regarding deformation from the non-pneumoperitoneum state tothe virtual pneumoperitoneum state. The image generator 162 may generatea surface from the volume data acquired in the non-pneumoperitoneumstate (for example, by preoperative CT scanning) to generate a surfacerendering image. The image generator 162 may apply the shape informationto the surface generated from the volume data acquired in thenon-pneumoperitoneum state (for example, by preoperative CT scanning) togenerate a surface rendering image of the virtual pneumoperitoneumstate.

The display controller 166 may cause the display 130 to visualize the 3Ddata (the volume rendering image or the surface rendering image of thevirtual pneumoperitoneum state) with an annotation of the port positionderived from the port position processing unit 164.

The projection controller 167 may project visible light to the portposition on the body surface of the subject PS (for example, a patient)derived by the port position processing unit 164 to indicate the portposition using the visible light and to visualize the port position. Asa result, the user can perform a treatment such as piercing on the portposition while checking the port position on the body surface of thesubject PS.

The projection controller 167 may project visible light to the subjectPS to display information regarding the port position on the bodysurface of the subject PS (for example, a patient) derived by the portposition processing unit 164. In this case, the projection controller167 may display the information regarding the port position (forexample, the identification information of the port or an arrowindicating the port position) to superimpose the subject PS using an ARtechnique. As a result, referring to guide information by the visiblelight, the user can perform a treatment such as piercing on the portposition while checking the information regarding the port position onthe body surface of the subject PS.

Here, the deformation information will be described in detail.

The deformation simulator 163 detects movement (deformation) of each ofthe portions included in the volume data to generate the deformationinformation based on the plurality of volume data (CT images) obtainedbefore and after pneumoperitoneum. In this case, the deformationsimulator 163 performs movement analysis (deformation analysis) on thedeformation of the plurality of volume data based on the plurality ofvolume data regarding the amount of pneumoperitoneum to acquire thedeformation information in the volume data. A specific method of thedeformation analysis is described in, for example, U.S. Pat. No.8,311,300 and Japanese Patent No. 5408493 which are incorporated hereinby reference. These methods are examples of non-rigid registration butmay be rigid registration.

The deformation simulator 163 may acquire, as the deformationinformation, information regarding the amount of movement or informationregarding the velocity at a given point of the volume data. When themethod described in US2014/0148816A which is incorporated herein byreference is applied, the deformation simulator 163 separates the volumedata into a 2D lattice node (k, l), and 2D coordinates (x, y) in a phasenode (k, l, t) of a phase t of the 2D lattice is obtained. In this case,based on a difference between a plurality of nodes (k, l, t) obtained bychanging the value of the phase t, the information regarding the amountof movement at the lattice point of the node (k, l) may be calculated Inaddition, the deformation simulator 163 may differentiate theinformation regarding the amount of movement with time to calculate theinformation regarding the velocity. The information regarding the amountof movement or the velocity may be expressed by a vector.

When the deformation simulator 163 interpolates the deformationinformation of the 2D lattice at each point of the entire volume data,the deformation information of each point of the volume data can beobtained. When the deformation information of a predetermined point isapplied to each point of a region including an observation site, thedeformation information of each point of the region including theobservation site can be obtained.

In addition, when the method described in Japanese Patent No. 5408493 isapplied, the deformation simulator 163 may generate the deformationinformation based on volume data tk−1 and time information tk−1 thereofand volume data tk and time information tk thereof among the volume data(before and after pneumoperitoneum) aligned in time series. Thedeformation information may indicate information regarding acorresponding position on the plurality of volume data or correspondenceof a corresponding object or information regarding the process of achange in the movement of the position and the object. A pixel of eachvolume data is an index indicating a position at any time between timek−1 and time k.

The deformation simulator 163 is not limited to the method ofUS2014/0148816A and may perform deformation analysis using anotherwell-known registration method. The robotically-assisted surgical device100 performs deformation analysis on each point or the observation siteusing the deformation information, and thus, the movement of anyposition in the subject before and after pneumoperitoneum can begrasped.

Next, a specific example of a standard port position will be described.

FIG. 5A is a view illustrating a first placement planning example ofport positions placed on the body surface of the subject PS. FIG. 5B isa view illustrating a second placement planning example of portpositions placed on the body surface of the subject PS. FIG. 5C is aview illustrating a third placement planning example of port positionsplaced on the body surface of the subject PS. The placement of aplurality of port positions may be planed, for example, according to thesurgical procedure. In FIGS. 5A to 5C, the physical size of the subjectPS or the position or size of a disease or the like of the observationtarget is not considered.

A plurality of port positions illustrated in FIGS. 5A to 5C are portpositions that are planned to be pierced. There may be some errorsbetween the port positions that are planned to be pierced and the portpositions that are actually pierced. For example, there may be an errorof about 25 mm.

The ports PT provided on the body surface of the subject PS may includea camera port PTC into which a camera CA is inserted, an end effectorport PTE into which the end effector EF is inserted, and an auxiliaryport PTA into which forceps held by an assistant are inserted. Aplurality of ports PT may be present for each of the types (for example,for each of the camera port PTC, the end effector port PTE, and theauxiliary port PTA), or the sizes of the different types of ports PT maybe the same as or different from each other. For example, the endeffector port PT E into which the end effector EF for holding an organor the end effector EF of which the movement in the subject PS iscomplex is inserted may be larger than the end effector port PTE intowhich the end effector EF as an electric knife is inserted. Theplacement position of the auxiliary port PTA may be planned relativelyfreely.

In FIG. 5A, large numbers of the end effector ports PTE and theauxiliary ports PTA are linearly arranged in the right direction of thesubject PS and in the left direction of the subject PS, respectively,with respect to the port position of the camera port PTC as a reference(the vertex).

In FIG. 5B, large numbers of end effector ports PTE and the auxiliaryports PTA are linearly aligned with a position of a navel hs interposedtherebetween. In addition, the camera port PTC is also placed near thenavel hs.

In FIG. 5C, large numbers of end effector ports PTE and the auxiliaryports PTA are linearly aligned. The position of the navel hs is slightlyshifted from the position on the straight line. In addition, the cameraport PTC is also placed near the navel hs.

The reason why a large amount of ports PT are linearly placed in anexisting plan is presumed to be that the user can easily recognize theport positions and feels safe. Among the plurality of ports PT, thecamera port PTC may be placed at the center of the body surface of thesubject PS.

FIG. 6 is a view illustrating an example of a positional relationshipbetween the subject PS, the ports PT, the trocars TC, and the robot armsAR during robotic surgery.

In the subject PS, one or more ports PT are provided. In each of theports PT, the trocar TC is placed. The end effector EF is connected (forexample, is inserted) to the trocar TC and a work (treatment) can beperformed using the end effector EF in the subject. The port position isdisposed to be fixed and does not move during operation. Accordingly,the position of the trocar TC disposed at the port position does notalso move. On the other hand, according to the treatment duringoperation, the robot arms AR and the end effectors are controlled basedon the manipulation of the robot operation terminal, and the robot armsAR move. Accordingly, the positional relationship between the robot armsAR and the trocars TC changes, and the angles of the trocars TC withrespect to the body surface of the subject or the angles of the endeffectors EF attached to the trocars TC change. In FIG. 6, a monitorheld by an assistant is also illustrated as an end effector.

Next, the operation of the robotically-assisted surgical device 100 willbe described.

First, the procedure of the port position simulation will be described.FIG. 7 is a flowchart illustrating an example of the procedure of theport position simulation.

First, the port position processing unit 164 acquires the volume dataincluding the subject PS, for example, via the communication unit 110(S11). The port position processing unit 164 acquires the kinematicinformation from the surgical robot 300, for example, via thecommunication unit 110 (S12). The deformation simulator 163 performs thepneumoperitoneum simulation (S13) to generate the volume data of thevirtual pneumoperitoneum state of the subject PS.

The port position processing unit 164 acquires the information of thesurgical procedure (S14). The port position processing unit 164 acquiresand sets the positions (initial positions) of the plurality of ports PTaccording to the acquired surgical procedure (S14). In this case, theport position processing unit 164 may set the positions of the pluralityof ports PT in terms of 3D coordinates.

The port position processing unit 164 acquires the information of thetarget region (S15).

The port position processing unit 164 determines whether or not each ofthe end effectors EF inserted from each of the ports PT is accessible tothe target region based on the positions of the plurality of portsacquired in S14 and the position of the target region (S16). Whether ornot each of the end effectors EF is accessible to the target region maycorrespond to whether or not each of the end effectors EF can reach allthe positions in the target region. That is, whether or not each of theend effectors EF is accessible to the target region shows that whetheror not robotic surgery can be performed by the end effector EF(optionally, the plurality of end effectors EF) according to theacquired surgical procedure, and when each of the end effectors EF isaccessible to the target region, robotic surgery can be performed.

When at least one of the end effectors EF is not accessible to at leasta part of the target region, the port position processing unit 164 movesa port position of at least one port PT included in the plurality ofports PT to be pierced along the body surface of the subject PS (S17).In this case, the port position processing unit 164 may move the portposition based on the user input via the UI 120. The port PT to be movedincludes at least a port PT into which the end effector EF that is notaccessible to at least a part of the target region is inserted.

When each of the end effectors EF is accessible to the target region,the processing unit 160 ends the process of the port position simulationof FIG. 7.

As described above, the robotically-assisted surgical device 100performs the port position simulation such that whether or not each ofthe end effectors EF is accessible to the target region using theacquired plurality of port positions can be determined and thus whetheror not robotic surgery can be performed by the surgical robot 300 usingthe acquired plurality of port positions can be determined. When thetarget region is not accessible using the plurality of port positions,at least a part of the port positions may be changed via the UI 120 todetermine again whether or not the target region is accessible using thechanged plurality of port positions. The robotically-assisted surgicaldevice 100 can plan a combination of a plurality of port positions thatare accessible to the target region as the plurality of port positionsto be pierced. This way, the robotically-assisted surgical device 100can plan the port position by the user manually adjusting the portposition.

Next, an example of calculating the port position score will bedescribed.

The plurality of port positions are determined, for example, accordingto the surgical procedure, and it may be assumed that each port positionis disposed at any positions on the body surface of the subject PS.Accordingly, as the combination of the plurality of port positions,various combinations of port positions may be assumed. One end effectorEF mounted on the robot arm AR can be inserted from one port PT into thesubject PS. Accordingly, a plurality of end effectors EF mounted on aplurality of robot arms AR can be inserted from a plurality of ports PTinto the subject PS.

A range where one end effector EF can reach the subject PS through theport PT is a working area (individual working area WA1) where a work(treatment in robotic surgery) can be performed by one end effector EF.Accordingly, an area where the individual working areas WA1 of theplurality of end effectors EF superimpose each other is a working area(entire working area WA2) where the plurality of end effectors EF cansimultaneously reach the inside of the subject PS through the pluralityof ports PT. In a treatment according to the surgical procedure, apredetermined number (for example, three) of end effectors EF needs tobe operated at the same time. Therefore, the entire working area WA2where the predetermined number of end effectors EF can simultaneouslyreach the inside of the subject PS is considered.

In addition, the position where the end effector EF can reach thesubject PS varies depending on the kinematics of the surgical robot 300,and thus is added to the derivation of a port position as a positionwhere the end effector EF is inserted into the subject PS. In addition,the position of the entire working area WA2 in the subject PS that isrequired to be secured varies depending on the surgical procedure, andthus is added to the derivation of a port position corresponding to theposition of the entire working area WA2.

The port position processing unit 164 may calculate the port positionscore for each of the acquired (assumed) combinations of the pluralityof port positions. The port position processing unit 164 may plan acombination of port positions having a port position score (for example,a maximum port score) that satisfies predetermined conditions among theassumed combinations of the plurality of port positions. That is, theplurality of port positions included in the planned combination of theport positions may be planned as the plurality of port positions to bepierced.

A relationship between the port position and the operation of the movingpart of the surgical robot 300 may satisfy a relationship described in,for example, Mitsuhiro Hayashibe, Naoki Suzuki, Makoto Hashizume, KozoKonishi, Asaki Hattori, “Robotic surgery setup simulation with theintegration of inverse-kinematics computation and medical imaging”,computer methods and programs in biomedicine, 2006, P63-P72 and PalJohan From, “On the Kinematics of Robotic-assisted Minimally InvasiveSurgery”, Modeling Identification and Control, Vol. 34, No. 2, 2013,P69-P82, which is incorporated herein by reference.

FIG. 8 is a flowchart illustrating an operation example when the portposition score is calculated by the robotically-assisted surgical device100.

Before the process of FIG. 8, the acquisition of the volume data of thesubject PS, the acquisition of the kinematic information of the surgicalrobot 300, the execution of the pneumoperitoneum simulation, and theacquisition of the information of the surgical procedure are performedin advance as in S11 to S14 of the port position simulation illustratedin FIG. 8. In addition, the kinematic information may include theinformation of each of the end effectors EF mounted on each robot armaccording to the surgical procedure. The initial value of the portposition score is 0. The port position score is an evaluation function(evaluation value) indicating the value of the combination of the portpositions. A variable i is an example of identification information of awork, and a variable j is an example of identification information of aport.

The port position processing unit 164 generates a work list works, whichis a list of works work_i in which each end effector EF is used,according to the surgical procedure (S21). The work work_i includesinformation for allowing each end effector EF to perform the work in thesurgical procedure according to the surgical procedure. The work work_imay include, for example, gripping, dissection, or suture. The work mayinclude a solo work that is performed by a single end effector EF or acooperative work that is performed by a plurality of end effectors EF.

Based on the surgical procedure and the volume data of the virtualpneumoperitoneum state, the port position processing unit 164 plans aminimum region least_region_i, which is a region necessary forperforming the works work_i included in the work list works (S22). Theminimum region may be specified as a 3D region in the subject PS. Theport position processing unit 164 generates a minimum region listleast_regions, which is a list of the minimum regions least_region_i(S22).

Based on the surgical procedure, the kinematics of the surgical robot300, and the volume data of the virtual pneumoperitoneum state, the portposition processing unit 164 plans an effective regioneffective_region_i that is recommended for performing the work work_iincluded in the work list works (S23). The port position processing unit164 generates an effective region list effective_regions, which is alist of the recommended regions effective_region_i (S23). Therecommended region may include not only the minimum space (minimumregion) for performing the work but also a space that is effective, forexample, the end effector EF to operate.

The port position processing unit 164 acquires information of a portposition list ports, which is a list of a plurality of port positionsport_j (S24). The port position may be specified by 3D coordinates (x,y, z). The port position processing unit 164 may receive, for example, auser input through the UI 120 to acquire the port position list portsincluding one or more port positions designated by the user. The portposition processing unit 164 may acquire the port position list portsthat are stored in the memory 150 as a template.

Based on the surgical procedure, the kinematics of the surgical robot300, the volume data of the virtual pneumoperitoneum state, and theacquired plurality of port positions, the port position processing unit164 plans a port working region region_i, which is a region where eachof the end effectors EF can perform each of the works work_i througheach of the port positions port_j (S25). The port working region may bespecified as a 3D region. The port position processing unit 164generates a port working region list regions, which is a list of theport working regions region_i (S25).

The port position processing unit 164 subtracts the port working regionregion_i from the minimum region least_region_i for each of the workswork_i to calculate a subtracted region (subtracted value) (S26). Theport position processing unit 164 determines whether or not thesubtracted region is an empty region (the subtracted value is negative)(S26). Whether or not the subtracted region is an empty region showsthat whether or not a region that is not covered with the port workingregion region_i (a region that cannot be reached by the end effector EFthrough the port PT) is present in at least a part of the minimum regionleast_region_i.

When the subtracted region is an empty region, the port positionprocessing unit 164 calculates a volume value volume_i, which is theproduct of the recommended region effective_region_i and the portworking region region_i (S27). The port position processing unit 164sums the volume values volume_i calculated for each of the works work_ito calculate a sum value volume_sum. The port position processing unit164 sets the sum value volume_sum as the port position score (S27).

That is when the subtracted region is an empty region, it is preferablethat the region that is not covered with the port working region is notpresent in the minimum region and this port position list ports (thecombination of the port positions port_j) is selected. Therefore, inorder to promote the selection of the port position list, the value foreach of the works work_i is added to the port position score. Inaddition, by planning the port position score based on the volume valuevolume_i, as the minimum region or the port working region increases,the port position score increases, and tins port position list ports ismore likely to be selected. Accordingly, the port position processingunit 164 is more likely to select a combination of port positions inwhich the minimum region or the port working region is large and eachtreatment is easy in surgery.

On the other hand, when the subtracted region is not an empty region,the port position processing unit 164 sets the port position score ofthe port position list ports to a value of 0 (S28). That is, since theregion that is not covered with the port working region is present in atleast a part of the minimum region and the work of the target workwork_i may not be completed, it is not preferable to select this portposition list ports. Thus, in order to make the selection of the portposition list ports difficult, the port position processing unit 164sets the port position score to a value of 0 and excludes the portposition list from candidates of the selection. In this case, when thesubtracted region is an empty region in a case where another work work_iis performed using the same port position list ports, the port positionprocessing unit 164 sets the port position score to a value of 0 as awhole.

The port position processing unit 164 may calculate a port positionscore for all the works work_i by repeating the respective steps of FIG.8 for all the works work_i.

As described above, the robotically-assisted surgical device 100 derivesthe port position score, and when the robotic surgery is performed usingthe plurality of port positions provided on the body surface of thesubject PS, the appropriateness of the combination of the port positionsto be pierced can be grasped. The individual working area WA1 and theentire working area WA2 depend on the placement positions of theplurality of ports to be pierced. Even in this case, by using a score(port position score) for each combination of a plurality of portpositions, the surgical robot 300 can derive a combination of aplurality of port positions in which, for example, the port positionscore is a threshold th1 or higher (for example, maximum), and the portpositions with which robotic surgery can be easily performed can be set.

In addition, by appropriately securing the working area based on theport position score, the user can secure a wide visual field in thesubject that cannot be directly visually observed in robotic surgery, awide port working region can be secured, and unexpected events can beeasily handled.

In addition, in robotic surgery, the port positions to be pierced arenot variable. However, the robot rums AR on which the end effectorsinserted into the port positions are mounted are movable in apredetermined range. Therefore, in robotic surgery, depending on theplanned port positions, the robot arms AR may interfere with each other.Therefore, port position planning is important. In addition, thepositional relationship between the surgical robot 300 and the subjectPS cannot be changed during operation in principle. Therefore, portposition planning is important.

FIG. 9 is a view illustrating an example of working areas determinedbased on the port positions. The individual working area WA1 is anindividual working area corresponding to each of the port positionsport_j. The individual working area WA1 may be a region in the subjectPS that can be reached by each of the end effectors EF. An area wherethe respective individual working areas WA1 superimpose each other isthe entire working area WA2. The entire working area WA2 may correspondto the port working region region_i. The robotically-assisted surgicaldevice 100 can optimize each of the port positions using the portposition score, and the suitable individual working areas WA1 and thesuitable entire working area WA2 can be derived.

Next, the details of the port position adjustment will be described.

The port position processing unit 164 acquires information of theplurality of port positions (candidate positions), for example, based onthe template stored in the memory 150 or the user instruction via UI120. The port position processing unit 164 calculates the port positionscore for the case using the plurality of port positions based on theacquired combination of the plurality of port positions.

The port position processing unit 164 may adjust the position of theport PT based on the port position score. In this case, the portposition processing unit 164 may adjust the position of the port PTbased on the port position score for the acquired plurality of portpositions and the port position score obtained when at least one portposition among the plurality of port positions is changed. In this case,the port position processing unit 164 may also consider a small movementor a differential of the port position in each of the directions (xdirection, y direction, and z direction) in a 3D space.

The x direction may be a direction along a left-right direction withrespect to the subject PS. The y direction may be a forward-backwarddirection (thickness direction of the subject PS) with respect to thesubject PS. The z direction may be an up-down direction (body axisdirection of the subject PS) with respect to the subject PS. The xdirection, the y direction, and the z direction may be three directionsdefined by Digital Imaging and Communications in Medicine (DICOM). The xdirection, the y direction, and the z direction may be directions otherthan the above-described directions and are not necessarily thedirections with respect to the subject PS.

For example, the port position processing unit 164 may calculate a portposition score F (ports) for the plurality of port positions accordingto (Expression 1) to calculate a differential value F′ of F.

F(port_j(x+Δx, y, z))−F(port_j(x, y, z))

F(port_j(x, y+Δy, z))−F(port_j(x, y, z))

F(port_j(x, y, z+Δz))−F(port_j(x, y, z))  (Expression 1)

That is, the port position processing unit 164 calculates the portposition score F for the port position F (port_j(x+Δx, y, z)),calculates the port position score F for the port position F (port_j(x,y, z)), and calculates a difference therebetween. This difference valueindicates a change in the port position score with respect to a smallchange of the port position F (port_j(x, y, z)) in the x direction, thatis, the differential value F′ of F in the x direction.

In addition, the port position processing unit 164 calculates the portposition score F for the port position F (port_j(x, y+Δy, z)),calculates the port position score F for the port position F (port_j(x,y, z)), and calculates a difference therebetween. This difference valueindicates a change in the port position score with respect to a smallchange of the port position F (port_j(x, y, z)) in the y direction, thatis, the differential value F′ of F in the y direction.

In addition, the port position processing unit 164 calculates the portposition score F for the port position F (port_j(x, y, z+Δz)),calculates the port position score F for the port position F (port_j(x,y, z)), and calculates a difference therebetween. This difference valueindicates a change in the port position score with respect to a smallchange of the port position F (port_j(x, y, z)) in the z direction, thatis, the differential value F′ of F in the z direction.

The port position processing unit 164 calculates a maximum value of theport position score based on the differential value F′ of each of thedirections. In this case, the port position processing unit 164 maycalculate a port position having the maximum port position scoreaccording to the steepest descent method based on the differential valueF′. The port position processing unit 164 may adjust the port positionto optimize the port position such that the calculated port position isa position to be pierced. Instead of the port position in which the portposition score is the maximum, the port position may be, for example, aposition in which the port position score is the threshold th1 or higheras long as the port position score is improved (increases).

The port position processing unit 164 may apply this port positionadjustment to the adjustment of another port position included in thecombination of the plurality of port positions or to the adjustment ofport positions of another combination of a plurality of port positions.As a result, the port position processing unit 164 can plan theplurality of ports PT of which the respective port positions areadjusted (for example, optimized) as the port positions to be pierced.

Regarding the plurality of port positions (coordinates of the portpositions), there may be an error of about a predetermined length (forexample, 25 mm) between a piercing-planned position and an actualpiercing position, and it is presumed that a port position planningaccuracy of 3 mm at most is sufficient. Therefore, the port positionprocessing unit 164 may set a plurality of port positions included inthe combination of port positions as piercing-planned positions perpredetermined length of the body surface of the subject PS, and the portposition score may be calculated for each of the plurality of portpositions. That is, the piercing-planned positions may be placed in alattice shape (grid) of the predetermined length (for example, 3 mm) onthe body surface of the subject PS. In addition, when it is assumed thatthe number of ports (for example, the number of intersections in alattice shape) on the body surface is n and the number of ports includedin the combination of port positions is m, the port position processingunit 164 may combine by sequentially selecting m port positions from nport positions and may calculate the port position score for each of thecombinations. This way, when the grid is not excessively small as in alattice shape having an interval of 3 mm, the calculation load of theport position processing unit 164 can be inhibited from being excessive,and the port position scores of all the combinations can be calculated.

The port position processing unit 164 may adjust the plurality of portpositions using a well-known method. The port position processing unit164 may plan the port positions to be pierced as the plurality of portpositions included in the adjusted combination of port positions. Thewell-known method of the port position adjustment may include techniquesdescribed in the followings: Shaun Selha, Pierre Dupont, Robert Howe,David Torchiana, “Dexterity optimization by port placement inrobot-assisted minimally invasive surgery”, SPIE International Symposiumon Intelligent Systems and Advanced Manufacturing, Newton, Mass., 28-31,2001; Zhi Li, Dejan Milutinovic, Jacob Rosen, “Design of a Multi-ArmSurgical Robotic System for Dexterous Manipulation”, Journal ofMechanisms and Robotics, 2016; and US2007/0249911A, which areincorporated herein by reference.

Next, the port position adjustment using the pre-pierced port will bedescribed.

When a plurality of ports are planned to be pierced, the port positionprocessing unit 164 may acquire information (measurement information)regarding the port position of the pre-pierced port PT1 that ispreviously pierced (for example, pierced firstly). The port positionprocessing unit 164 may plan a port position of a port that is to bepierced next (for example, pierced secondly) based on the port positionof the pre-pierced port PT 1. As a result, even when there is adifference between the position of the port PT that is planned to bepierced and the position of the pre-pierced port PT1 that is actuallypierced, the robotically-assisted surgical device 100 can change theport position of the port that is to be pierced next.

FIG. 10 is a flowchart illustrating an example of a port positionadjustment procedure using the pre-pierced port PT1 by therobotically-assisted surgical device 100. In FIG. 10, the acquisition ofthe volume data of the subject PS, the acquisition of the kinematicinformation of the surgical robot 300, the execution of thepneumoperitoneum simulation, and the acquisition of the information ofthe surgical procedure are performed in advance as illustrated in FIG.8.

The port position processing unit 164 acquires information of aplurality of port positions (positions of piercing candidates) (S31).The port position processing unit 164 performs the port positionsimulation to calculate the port position score based on the acquiredplurality of port positions (S32). In this case, the port positionprocessing unit 164 may calculate the port position score based on thesurgical procedure, the kinematics of the surgical robot 300, the volumedata of the virtual pneumoperitoneum state, and the acquired pluralityof port positions.

The port position processing unit 164 calculates influence on the portposition score when each port position is temporarily moved (S33). Inthis case, the port position processing unit 164 may calculate, as theinfluence, an amount of the change (for example, a decrease) in portposition score when the port position is moved by a predetermineddistance (for example, a small distance). The amount of the change inport position score when the port position is moved by the predetermineddistance may be calculated according to (Expression 1) above, that is,may correspond to the differential value F′ of the port position scoreF.

The port position processing unit 164 plans the piercing order of theports PT such that the ports PT are pierced in order from the port PThaving the highest influence. The display controller 166 or theprojection controller 167 may display information regarding the positionof each port PT and the piercing order (S34). As a result, the user (forexample, an operator or an assistant) can easily recognize the plannedport positions and can also easily recognize the piercing order inconsideration of the influence.

For example, the piercing order may match the descending order of theinfluence. However, the piercing order may match the ascending order ofthe influence

The influence corresponds to the amount of change in port position scorewhen the port position is changed, and thus the influence can be alsosaid as the degree of necessity of piercing accuracy. That is, it can besaid that a port PT having a high influence is a port having a highdegree of necessity of piercing accuracy, and it can be said that a portPT having a low influence is a port having a low degree of necessity ofpiercing accuracy. Accordingly, the display of the piercing order as thedescending order of the influence can be said as an instruction to theuser for piercing the ports in order from the port having the highestdegree of necessity of piercing accuracy. Also, the display of thepiercing order as the ascending order of the influence can be said as aninstruction to the user for piercing the ports in order from the porthaving the lowest degree of necessity of piercing accuracy.

The user pierces the corresponding port at the planned port position.The user installs the trocar TC at the pierced port PT (pre-pierced portPT1). The measuring instrument 400 measures the port position of thepre-pierced port PT1. The port position of the pre-pierced port PT1 maybe automatically measured using the trocar TC or the like andtransmitted to the robotically-assisted surgical device 100, or may bemanually measured and then the measurement result may be input via theUI 120. The port position processing unit 164 may acquire measurementinformation of the port position of the pre-pierced port PT1 via thecommunication unit 110 or the UI 120 (S35). In addition, the portposition processing unit 164 may acquire identification information foridentifying the pre-pierced port PT1 via the UI 120. As a result, therobotically-assisted surgical device 100 can identify the pierced portamong the acquired positions of the plurality of ports.

The port position processing unit 164 replaces a port position of apiercing candidate corresponding to the pre-pierced port PT1 among theplurality of port positions acquired in S31 with the port position ofthe pre-pierced port PT1. Based on the plurality of port positionsobtained by the replacement, the port position processing unit 164calculates the port position score (the port position score inconsideration of the pre-pierced port PT1) for the combination of theplurality of port positions obtained by the replacement (S36). In thiscase, the port position processing unit 164 may calculate the portposition score based on the surgical procedure, the kinematics of thesurgical robot 300, the volume data of the virtual pneumoperitoneumstate, and the plurality of port positions obtained by the replacement.

The port position processing unit 164 adjusts and plans the remainingport positions based on the port position score in consideration of thepre-pierced port PT1 (S37). The port position processing unit 164 mayperform the adjustment of the remaining port positions using theabove-described method of the port position adjustment.

The port position of the pre-pierced port PT1 that is previously piercedis a fixed position, and the remaining port positions that have been notyet pierced are variable positions. Therefore, the port positionprocessing unit 164 proceeds to S31 after S37 and may freely change theremaining port positions among the plurality of port positions includingthe pre-pierced port PT1 to change the combination of the plurality ofport positions. The process of FIG. 10 may be repeatedly performed onthe changed combination of the plurality of port positions. The portposition processing unit 164 may plan the remaining port positions so asto be a combination of a plurality of port positions in which, forexample, the port position score is the threshold th1 or higher (forexample, maximum). As a result, the appropriateness of the remainingport positions can be improved (for example, optimized) in considerationof the pre-pierced port PT1.

When the port position processing unit 164 derives the piercing order inS34 in the repeated process of FIG. 10, since the pre-pierced port PT1is previously pierced, and the piercing order is fixed. Accordingly,here, the port position processing unit 164 derives the piercing orderof the remaining ports.

According to the port position adjustment procedure using thepre-pierced port PT1, even when the port PT is pierced at a positionmisplaced from the piercing-planned position, the robotically-assistedsurgical device 100 can adjust the remaining port positions inconsideration of the port position of the pre-pierced port PT1.Accordingly, even when the operation efficiency or the safety of roboticsurgery is likely to deteriorate with the derived combination of theplurality of port positions due to the error of the piercing position ofthe pre-pierced port PT1, deterioration in the operation efficiency andthe safety can be suppressed by replacing the remaining port positionsin consideration of the pre-pierced port PT1.

FIG. 11A is a view illustrating an image display example including aguide display before piercing a port. FIG. 11B is a view illustrating animage display example including a guide display after piercing the port.This image is the example displayed in the display 130. However, guideinformation for piercing the port PT may project visible light from theprojection unit 170 to the body surface of the subject PS to display theguide information using the visible light.

In FIG. 11A, the volume rendering image is displayed, and the guideinformation is also displayed to superimpose the volume rendering image.In the guide information, the presence of the port PT (port A) is shownat a head side of a large arrow, and identification information (forexample, “A”) of the port PT is shown in a tail side (base side) of thelarge arrow. In addition, in the guide information, a small arrow showsa distance between head positions of two direction arrows. In FIG. 11A,the distance is expressed in mm units. In addition, the position of thenavel hs is also shown by an arrow.

In FIG. 11B, the volume rendering image is displayed, and the guideinformation is also displayed to superimpose the volume rendering image.In the guide information, the presence of the port PT (port A) is shownat a head side of a large arrow, and identification information (forexample, “A”) of the port is shown in a tail side (base side) of thelarge arrow. In addition, by adding “opened”, it is shown that the portPT is the pre-pierced port PT1. For example, “opened A” shows that theport A is the pre-pierced port. In addition, in the guide information, asmall arrow shows a distance between head positions of two directionarrows. In FIG. 11B, the distance is expressed in mm units. In addition,the position of the navel hs is also shown by an arrow.

Next, designation examples of port positions according to ComparativeExample and the embodiment will be described.

FIG. 12 is a view illustrating a designation example of port positionsaccording to Comparative Example. As illustrated in FIG. 12, all theport positions to be pierced are determined before operation (beforepiercing the initial port). In FIG. 12, A, B, C, D, and E are examplesof the identification information of the ports, and the lengths thereofare expressed in mm units. The respective values illustrated in FIG. 12are merely exemplary and may be other values.

In FIG. 12, a port position of a port C is planned (designated) at aposition moved from the navel hs to the head side in the body axisdirection such that the distance between the navel hs and the port Cbecomes 20 mm. In addition, the ports A, B, C, D, and E are planned suchthat the ports A to E are linearly placed in a direction perpendicularto the body axis direction. That is, the ports A, B, C, D, and E areplanned such that the distance between the port A and the port B is 50mm, the distance between the port B and the port C is 50 mm, thedistance between the port C and the port D is 60 mm, and the distancebetween the port D and the port E is 40 mm.

FIG. 13 is a view illustrating a designation example of port positionsaccording to the present embodiment. In FIG. 13, “PT1” shows thepre-pierced port that is previously pierced, and “PT2” shows anon-pierced port that has been not yet pierced.

In FIG. 13, first, the positions of the ports A to E are planned, forexample, before operation by the first simulation of port position orthe first adjustment of port position. The positions are the same as theport positions planned in Comparative Example. That is, the portposition of the port C is planned at a position moved from the navel hsto the head side in the body axis direction such that the distancebetween the navel hs and the port C becomes 20 mm. In addition, the portposition of the port B is planned at a position moved from the navel hsin a direction perpendicular to the body axis direction such that thedistance between the port B and the port C is 50 mm. For example, theplanned port positions are pierced in order of the port C and the portB.

When the measuring instrument 400 measures the positions of the ports Band C that are actually pierced, the piercing position of the port C isthe same as the planned port position. On the other hand, the piercingposition of the port B is different from the planned port position, andthe port B is pierced at a position moved from the navel hs in adirection perpendicular to the body axis direction such that thedistance between the port B and the port C is 60 mm.

Regarding the above, the port position processing unit 164 performs theport position simulation or the port position adjustment again. Here,the port position adjustment is the port position adjustment using thepre-pierced port PT1. In this case, while the positions of the port Cand the port B as the pre-pierced ports PT1 are fixed (fixed value) andthe positions of the other ports A, D and E are set to be variable(variable values), each of the port positions is adjusted and planned.As a result of the port position simulation, in FIG. 13, the position ofthe port as the remaining port is changed from the originalpiercing-planned position (position planned by the first simulation ofport position or the first adjustment of port position), and the portposition is adjusted. That is, the port position of the port A isplanned at a position at a distance of 45 mm from the port position ofthe port B in a direction (left direction in FIG. 13) perpendicular tothe body axis direction and at a distance of 10 mm from the portposition of the port B in a direction (upper direction in FIG. 13) alongthe body axis direction. That is, the port position processing unit 164adjusts and plans the port position of the port A at a position in whichthe distance between the port A and the port B (the distance in thedirection perpendicular to the body axis direction) is 45 mm and that isoffset by 10 mm in the body axis direction.

Next, the variation of the port position adjustment using thepre-pierced port PT1 will be described.

The port position processing unit 164 may set a difficult-to-use region,which is a region where it is difficult to pierce a port on the bodysurface of the subject PS. The difficult-to-use region may include aregion where it is difficult to provide a port, for example, due tomedical history and adhesion or the like. The port position processingunit 164 may receive a user input via the UI 120 to designate thedifficult-to-use region. Setting information of the difficult-to-useregion may be stored in the memory 150 to be appropriately referred to.The port PT included in the difficult-to-use region is an inappropriateport to be inappropriate for the piercing the port PT. Thisinappropriate port may also be a non-pierced port or a pierced port. Theport position processing unit 164 may prevent the port to be piercedfrom being provided in the difficult-to-use region or may allow the portto be pierced to be provided in the difficult-to-use region.

In addition, when the pre-pierced port PT1 is actually pierced and isdifficult to use, the port position processing unit 164 may set apredetermined region including the pre-pierced port PT1 as thedifficult-to-use region. The port position processing unit 164 mayreceive a user input via the UI 120 to acquire information indicatingthat the pre-pierced port PT1 is difficult to use. In this case, thepre-pierced port PT1 is an inappropriate port that is inappropriate forthe piercing the port PT.

The port position processing unit 164 may reduce the priority ofpiercing of the port PT present in the difficult-to-use region such thatthe piercing order is planned to be the order from the highest priority.As a result, since the robotically-assisted surgical device 100 does notpierce the difficult-to-use region such as adhesion as long as possible,and attention can be paid not to damage the body surface of the subjectPS corresponding to the difficult-to-use region foal is less likely tobe used.

Conversely, the port position processing unit 164 may increase thepriority of piercing of the port PT present in the difficult-to-useregion such that the piercing order is planned to be the order from thehighest priority. As a result, the robotically-assisted surgical device100 tries to pierce the difficult-to-use region such as adhesion in anearly stage. Therefore, the state of the difficult-to-use region can bechecked in an early stage, and the next port piercing plan can be easilymade.

Among the acquired or planned plurality of ports, the inappropriate portmay be separated from ports (appropriate ports) other than theinappropriate port by a distance of a threshold th2 or more. As aresult, when the appropriate port is pierced, the robotically-assistedsurgical device 100 can reduce the influence of, for example, factors(for example, adhesion) that make the vicinity of the inappropriate portdifficult to pierce.

The display controller 166 or the projection controller 167 mayvisualize the difficult-to-use region or the inappropriate port. Thatis, the display controller 166 may display an inappropriateness markindicating the difficult-to-use region or the inappropriate port at aposition corresponding to the difficult-to-use region or theinappropriate port in the rendering image based on the volume data. Theprojection controller 167 may project visible light to thedifficult-to-use region on the body surface of the subject PS to displayan inappropriateness mark indicating the difficult-to-use region. Thedisplay controller 166 or the projection controller 167 may display, asthe inappropriateness mark, for example, “!” mark for displaying theport or a specific reason such as “possible adhesion” for thedetermination of the difficult-to-use region.

In the above-described example, the port position processing unit 164derives the piercing order in consideration of the influence on themovement of a predetermined port itself. However, the port positionprocessing unit 164 may derive (for example, calculate) the piercingorder in consideration of influence (other influence) of other portsthan the predetermined port. When the port position processing unit 164adjusts the position of the predetermined port such that the distancebetween the predetermined port and other ports is a predetermineddistance or less, the port position processing unit 164 may determinethat the other influence is high and may increase or reduce the priorityto derive the piercing order. In addition, when the port positionprocessing unit 164 adjusts the position of the predetermined port suchthat the positions of the other ports are required to be adjusted andthe working area also changes, the port position processing unit 164 maydetermine that the other influence is high and may increase or reducethe priority to derive the piercing order. As a result, by taking theother influence into consideration, the robotically-assisted surgicaldevice 100 can suppress, for example, a change in the working area inwhich the other ports are used, that is, can suppress deterioration inthe workability of robotic surgery in which the other ports are used. Asa result, the workability of robotic surgery in which the predeterminedport is used can be improved.

The port position processing unit 164 may plan the piercing order basedon the piercing difficulty of the port PT. The piercing difficultyindicates the difficulty of piercing the port PT to be pierced. Forexample, as the distance from a reference position (for example, thenavel h or another port) increases, the piercing difficulty mayincrease. That is, when the distance from the reference position to theport PT to be pierced is long, the distance is likely to deviate fromthe desired distance during the measurement of the distance. Therefore,it is difficult to pierce the port PT to be pierced. In addition, a portthat is pierced through the side of the subject PS may have highpiercing difficulty. The port position processing unit 164 may acquireinformation on the piercing difficulty stored in the memory 150.

The port position processing unit 164 may plan the piercing order of theports PT such that the ports PT are pierced in order from the porthaving the highest piercing difficulty. The display controller 166 orthe projection controller 167 may display information regarding thepiercing order in consideration of the position of each port PT and thepiercing difficulty. As a result, the user (for example, an operator oran assistant) can easily recognize the planned port positions and canalso easily recognize the piercing order in consideration of thepiercing difficulty.

After piercing a plurality of ports PT, the port position processingunit 164 may set the plurality of ports PT as the pre-pierced ports PT1to adjust the remaining port positions to be pierced. In this case, bysetting the port positions of the plurality of pre-pierced ports PT1 asfixed positions and setting the remaining port positions other than theplurality of pre-pierced ports PT1 as variable positions, the portposition processing unit 164 may perform the port position simulation orthe port position adjustment to adjust the remaining port positions. Asa result, for example, a plurality of persons pierce the ports PT at thesame time, the robotically-assisted surgical device 100 can adjust theremaining port positions in consideration of the piercing result of theplurality of pierced ports as the pre-pierced port PT1.

When the pre-pierced port PT1 is pierced, the deformation simulator 163may acquire information on the position of the body surface of thesubject PS in the actual pneumoperitoneum state from the measuringinstrument 400 via the communication unit 110. The deformation simulator163 may acquire information on the position of the body surface of thesubject PS in the virtual pneumoperitoneum state that is obtained byperforming the pneumoperitoneum simulation on the volume data of thesubject PS in the non-pneumoperitoneum state. The deformation simulator163 may correct the result of the pneumoperitoneum simulation togenerate correction information for the correction based on a differencebetween the position of the body surface of the subject PS in the actualpneumoperitoneum state and the position of the body surface of thesubject PS in the virtual pneumoperitoneum state.

Referring to the correction information, the port position processingunit 164 may perform the port position simulation or the port positionadjustment based on the volume data of the virtual pneumoperitoneumstate on which the corrected pneumoperitoneum simulation is performed.As a result, the robotically-assisted surgical device 100 can improvethe adjustment accuracy of the port position adjustment using thepre-pierced port PT1.

Hereinbefore, various embodiments have been described with reference tothe drawings. However, it is needless to say that the present disclosureis not limited to these examples. It is obvious to those skilled in theart that various changes or modifications can be conceived within thescope of the claims. Of course, it can be understood that these changesor modifications belong to the technical scope of the present disclosure

In the first embodiment, the volume data as the captured CT images aretransmitted from the CT apparatus 200 to the robotically-assistedsurgical device 100. Instead, the volume data may be transmitted to anetwork server to temporarily accumulate the data and then stored in aserver or the like. In this case, as necessary, the communication unit110 of the robotically-assisted surgical device 100 may acquire thevolume data from the server or the like via a wired circuit or awireless circuit, or may acquire the volume data via any storage medium(not illustrated).

In the first embodiment, the volume data as the captured CT images aretransmitted from the CT apparatus 200 to the robotically-assistedsurgical device 100 via the communication unit 110. This example alsoincludes a case where the CT apparatus 200 and the robotically-assistedsurgical device 100 are substantially integrated into one product. Inaddition, the example may also include a case where therobotically-assisted surgical device 100 is considered as a console ofthe CT apparatus 200.

In the first embodiment, the CT apparatus 200 captures images togenerate volume data including information regarding the inside of anorganism. However, another device may capture images to generate volumedata. Examples of the other device include a Magnetic Resonance imaging(MRI) device, a Positron Emission Tomography (PET) device, anangiographic device, and other modality devices. In addition, the PETdevice may be used in combination with other modality devices.

In the first embodiment, the surgical robot 300 is connected to therobotically-assisted surgical device 100. However, the surgical robot300 is not necessarily connected to the robotically-assisted surgicaldevice 100. The reason is for this is that this connection is notparticularly limited as long as the kinematic information of thesurgical robot 300 is acquired in advance. In addition, the surgicalrobot 300 may be connected after the end of the piercing of the ports.In addition, only a device that is a part of devices constituting thesurgical robot 300 may be connected to the robotically-assisted surgicaldevice 100. In addition, the robotically-assisted surgical device 100itself may be a part of the surgical robot 300.

In the first embodiment, the surgical robot 300 is a surgical robot forminimal invasion. However, the surgical robot 300 for minimal invasionmay be a surgical robot that assists laparoscopic surgery. In addition,the surgical robot 300 may be a surgical robot that assists endoscopicsurgery.

In the first embodiment, the robotically-assisted surgical device 100plans the port positions based on the volume data of the virtualpneumoperitoneum state of the subject, but the present disclosure is notlimited thereto. For example, when the observation target is arespiratory organ or a cervical part, robotic surgery may be performedwithout pneumoperitoneum. That is, the robotically-assisted surgicaldevice 100 may plan the port positions based on the volume data of thenon-pneumoperitoneum state.

In the first embodiment, the subject PS is a human body but may be ananimal body.

The present disclosure is also applicable to a program that implementsthe function of the robotically-assisted surgical device according tothe first embodiment, in which the program is supplied to therobotically-assisted surgical device via a network or various storagemedia and is read and executed by a computer in the robotically-assistedsurgical device.

As described above, the robotically-assisted surgical device 100according to the embodiment assists minimally invasive robotic surgeryby the surgical robot 300. The processing unit 160 may acquire 3D dataof the subject PS (for example, the volume data of thenon-pneumoperitoneum state or the volume data of the virtualpneumoperitoneum state). The processing unit 160 may acquire operationinformation (for example, kinematic information) regard to a moving part(for example, the robot arm AR or the end effector EF) of the surgicalrobot for performing the robotic surgery. The processing unit 160 mayacquire information of a surgical procedure for operating the subjectPS. The processing unit 160 may acquire position planning informationfor a plurality of ports PT that are to be pierced on a body surface ofthe subject PS. The processing unit 160 may acquire measurementinformation obtained by measuring the position of a first port (forexample, the pre-pierced port PT1) that is pierced on the body surfaceof the subject PS among the plurality of ports PT. The processing unit160 may determine a position of at least one of remaining ports otherthan the first port among the plurality of ports PT based on themeasurement information of the position of the first port, the surgicalprocedure, the operation information (the kinematic information) of thesurgical robot, and the 3D data. The processing unit 160 may displayinformation indicating the determined position of the port in a displayunit (for example, the display 130).

As a result, the robotically-assisted surgical device 100 can pierce theport PT while adjusting the port position during the piercing of theplurality of ports PT. For example, when the port PT is at a positionthat is difficult to pierce, it may be difficult to pierce the port atthe originally planned position, and the port may be pierced at aposition other than the planned position. Even in this case, therobotically-assisted surgical device 100 plans the remaining portpositions (non-pierced ports) in consideration of the piercing positionof the port PT (pre-pierced port) that is actually pierced such that abalance of the originally planned placement of the plurality of ports PTas a whole can be easily secured. Accordingly, the robotically-assistedsurgical device 100 can reduce the influence of the misplacement of thefirst port from the piercing-planned position on robotic surgery.

In addition, the processing unit 160 may adjust positions of theplurality of ports PT including the first port and the remaining portsbased on the acquired positions of the plurality of ports PT, thesurgical procedure, the operation information of the surgical robot 300,and the 3D data. The processing unit 160 may readjust an adjustedposition of at least one of the remaining ports among the plurality ofports based PT on the position of the pierced first port, the surgicalprocedure, the operation information of the surgical robot, and the 3Ddata.

As a result, the robotically-assisted surgical device 100 can adjust(for example, optimize) the placement of all the plurality of portsfirst and then can plan the placement suitable for all the plurality ofports. In addition, the robotically-assisted surgical device 100 canreadjust the placement of the remaining ports in consideration of thepiercing position of the first port that is actually pierced and thencan plan the placement suitable for all the remaining ports.Accordingly, the robotically-assisted surgical device 100 can adjusteach port position, for example, for each piercing and can optimize theposition of a non-pierced port at each piercing timing.

In addition, the processing unit 160 may derive a priority (for example,the influence, the other influence, or the piercing difficulty) ofpiercing the remaining ports on the body surface of the subject PS. Theprocessing unit 160 may plan the piercing order (an example of planningof the priority) for piercing the remaining ports based on the priority.The processing unit 160 may display information regarding the piercingorder.

As a result, the user can recognize the desired piercing order forpiercing the non-pierced ports. For example, the robotically-assistedsurgical device 100 can increase the priority of a port in which themisplacement (error) of the piercing position has a high influence onthe port positron score such that the ports can be promoted to bepierced in order from the port having the highest influence on the portpositron score.

In addition, the processing unit 160 may designate, via the UI 120, aninappropriate port that is included in the plurality of ports PT and isinappropriate to be pierced. A distance between the inappropriate portand a port (appropriate port) that is not designated as theinappropriate port among the plurality of ports PT may be a thresholdth2 or more.

As a result, the user can recognize the inappropriate port that isinappropriate as a target to be pierced. In addition, by setting thedistance the inappropriate port and the appropriate port other than theinappropriate port to be within a predetermined distance, the influenceof, for example, adhesion in the vicinity of the inappropriate port canbe reduced during the piercing of the appropriate port.

In addition, the processing unit 160 may cause the display unit (forexample, the display 130) to visualize the 3D data with an annotation ofthe information of the remaining ports (for example, the identificationinformation of the remaining ports or the information of the portpositions of the remaining ports) to superimpose the rendering image.

As a result, the user can recognize the positions of the remaining portson the subject PS on the display unit. In addition, therobotically-assisted surgical device 100 uses the 3D data such that theuser can estimate the influence of the piercing of the remaining portson the inside of the subject PS.

In addition, the processing unit 160 may cause a projection unit 170 toproject visible light representing information of the remaining ports tothe body surface of the subject PS.

As a result, the robotically-assisted surgical device 100 can directlyproject the information of the remaining ports to the subject PS onwhich robotic surgery is performed. Therefore, the user can recognizethe information (for example, the position information of the port, theidentification information of the port, or the information of thepiercing order of the port) of the remaining ports projected to thesubject PS to be pierced. Accordingly, the user can pierce the portusing the visible light on the subject PS as a mark. Accordingly, therobotically-assisted surgical device 100 can suppress misplacement ofthe actual piercing positions from the planned port positions of theremaining ports.

In addition, the processing unit 160 may perform a pneumoperitoneumsimulation on volume data of the subject PS to generate the 3D data of avirtual pneumoperitoneum state.

As a result, for example, even when the actual pneumoperitoneum state isdifferent from the pneumoperitoneum simulation state and the port ispierced at a position other than the planned position, therobotically-assisted surgical device 100 plans the remaining portpositions (non-pierced ports) in consideration of the piercing positionof the port PT (pre-pierced port) that is actually pierced, and abalance of the originally planned placement of the plurality of ports PTas a whole can be easily secured. Accordingly, in consideration of thestate of pneumoperitoneum of the subject, live robotically-assistedsurgical device 100 can reduce the influence of the misplacement of thefirst port from the piercing-planned position on robotic surgery.

The present disclosure is useful for, for example, arobotically-assisted surgical device capable of reducing the influenceof misplacement of a pre-pierced port on robotic surgery, arobotically-assisted surgery method, and a program.

What is claimed is:
 1. A robotically-assisted surgical device thatassists minimally invasive robotic surgery with a surgical robot thatincludes at least one robot arm holding a surgical instrument, therobotically-assisted surgical device comprising a processing unit and adisplay unit, wherein the processing unit is configured to: acquire 3Ddata of a subject; acquire kinematic information regard to the robotarm; acquire information of a surgical procedure for operating thesubject; acquire position planning information for a plurality of portswhich are to be pierced on a body surface of the subject; acquiremeasurement information obtained by measuring a position of a first portwhich is pierced on the body surface among the plurality of ports;determine a position of at least one of remaining ports other than thefirst port among the plurality of ports, based on the measurementinformation of the position of the first port, the information of thesurgical procedure, the kinematic information, and the 3D data; andcause the display unit to display information indicating the determinedposition of the at least one of remaining ports.
 2. Therobotically-assisted surgical device according to claim 1, wherein theprocessing unit is configured to: adjust positions of the plurality ofports including the first port and the remaining ports, based on theacquired positions of the plurality of ports, the information of thesurgical procedure, the kinematic information, and the 3D data; andreadjust an adjusted position of at least one of the remaining portsamong the plurality of ports, based on the position of the pierced firstport, the information of the surgical procedure, the kinematicinformation, and the 3D data.
 3. The robotically-assisted surgicaldevice according to claim 1, wherein the processing unit is configuredto: derive a priority of piercing the remaining ports on the bodysurface; and cause the display unit to display information regarding thepriority.
 4. The robotically-assisted surgical device according to claim1, further comprising an operation unit, wherein the processing unit isconfigured to designate, via the operation unit, an inappropriate portwhich is included in the plurality of ports and which is inappropriateto be pierced, and a distance between the inappropriate port and a portwhich is not designated as the inappropriate port among the plurality ofports is equal to or longer than a threshold.
 5. Therobotically-assisted surgical device according to claim 1, wherein theprocessing unit is configured to: cause the display unit to visualizethe 3D data with an annotation of the information of the remainingports.
 6. The robotically-assisted surgical device according to claim 1,wherein the processing unit is configured to cause a projection unit toproject visible light representing information of the remaining ports tothe body surface.
 7. The robotically-assisted surgical device accordingto claim 1, wherein the processing unit is configured to perform apneumoperitoneum simulation on volume data of the subject to generatethe 3D data of a virtual pneumoperitoneum state.
 8. Arobotically-assisted surgery method of a robotically-assisted surgicaldevice that assists robotic surgery with a surgical robot that includesat least one robot arm holding a surgical instrument, therobotically-assisted surgery method comprising: acquiring 3D data of asubject; acquiring kinematic information regard to a moving part of thesurgical robot for performing the robotic surgery; acquiring informationof a surgical procedure for operating the subject; acquiring positionplanning information for a plurality of ports which are to be pierced ona body surface of the subject; acquiring measurement informationobtained by measuring a position of a first port which is pierced on thebody surface among the plurality of ports; determining a position of atleast one of remaining ports other than the first port among theplurality of ports, based on the measurement information of the positionof the first port, the information of the surgical procedure, thekinematic information, and the 3D data; and causing a display unit todisplay information indicating the determined position of the at leastone of remaining ports.
 9. The robotically-assisted surgery methodaccording to claim 8, further comprising: adjusting positions of theplurality of ports including the first port and the remaining ports,based on the acquired positions of the plurality of ports, theinformation of the surgical procedure, the kinematic information, andthe 3D data; and readjusting an adjusted position of at least one of theremaining ports among the plurality of ports, based on the position ofthe pierced first port, the information of the surgical procedure, thekinematic information, and the 3D data.
 10. The robotically-assistedsurgery method according to claim 8, further comprising: deriving apriority of piercing the remaining ports on the body surface; andcausing the display unit to display information regarding the priority.11. The robotically-assisted surgery method according to claim 8,further comprising: designating an inappropriate port which is includedin the plurality of ports and which is inappropriate to be pierced,wherein a distance between the inappropriate port and a port which isnot designated as the inappropriate port among the plurality of ports isequal to or longer than a threshold.
 12. The robotically-assistedsurgery method according to claim 8, further comprising: causing thedisplay unit to visualize the 3D data with an annotation of theinformation of the remaining ports.
 13. The robotically-assisted surgerymethod according to claim 8, further comprising: causing a projectionunit to project visible light representing information of the remainingports to the body surface.
 14. The robotically-assisted surgery methodaccording to claim 8, further comprising: performing a pneumoperitoneumsimulation on volume data of the subject to generate the 3D data of avirtual pneumoperitoneum state.
 15. A robotically-assisted surgerysystem of a robotically-assisted surgical device that assists roboticsurgery with a surgical robot that includes at least one robot armholding a surgical instrument, the robotically-assisted surgery systemcomprising: acquiring 3D data of a subject; acquiring kinematicinformation regard to a moving part of the surgical robot for performingthe robotic surgery; acquiring information of a surgical procedure foroperating the subject; acquiring position planning information for aplurality of ports which are to be pierced on a body surface of thesubject; acquiring measurement information obtained by measuring aposition of a first port which is pierced on the body surface among theplurality of ports; determining a position of at least one of remainingports other than the first port among the plurality of ports, based onthe measurement information of the position of the first port, theinformation of the surgical procedure, the kinematic information, andthe 3D data; and causing a display unit to display informationindicating the determined position of the at least one of remainingports.
 16. The robotically-assisted surgery system according to claim15, further comprising: adjusting positions of the plurality of portsincluding the first port and the remaining ports, based on the acquiredpositions of the plurality of ports, the information of the surgicalprocedure, the kinematic information, and the 3D data; and readjustingan adjusted position of at least one of the remaining ports among theplurality of ports, based on the position of the pierced first port, theinformation of the surgical procedure, the kinematic information, andthe 3D data.
 17. The robotically-assisted surgery system according toclaim 15, further comprising: deriving a priority of piercing theremaining ports on the body surface; and causing the display unit todisplay information regarding the priority.
 18. The robotically-assistedsurgery system according to claim 15, further comprising: designating aninappropriate port which is included in the plurality of ports and whichis inappropriate to be pierced, wherein a distance between theinappropriate port and a port which is not designated as theinappropriate port among the plurality of ports is equal to or longerthan a threshold.
 19. The robotically-assisted surgery system accordingto claim 15, further comprising: causing the display unit to visualizethe 3D data with an annotation of the information of the remainingports.
 20. The robotically-assisted surgery system according to claim15, further comprising: causing a projection unit to project visiblelight representing information of the remaining ports to the bodysurface.